Technology roadmap for cold-atoms based quantum inertial sensor in space

Sven Abend; Baptiste Allard; Aidan S. Arnold; Ticijana Ban; Liam Barry; Baptiste Battelier; Ahmad Bawamia; Quentin Beaufils; Simon Bernon; Andrea Bertoldi; Alexis Bonnin; Philippe Bouyer; Alexandre Bresson; Oliver S. Burrow; Benjamin Canuel; Bruno Desruelle; Giannis Drougakis; René Forsberg; Naceur Gaaloul; Alexandre Gauguet; Matthias Gersemann; Paul F. Griffin; Hendrik Heine; Victoria A. Henderson; Waldemar Herr; Simon Kanthak; Markus Krutzik; Maike D. Lachmann; Roland Lammegger; Werner Magnes; Gaetano Mileti; Morgan W. Mitchell; Sergio Mottini; Dimitris Papazoglou; Franck Pereira dos Santos; Achim Peters; Ernst Rasel; Erling Riis; Christian Schubert; Stephan Tobias Seidel; Guglielmo M. Tino; Mathias Van Den Bossche; Wolf von Klitzing; Andreas Wicht; Marcin Witkowski; Nassim Zahzam; Michał Zawada

doi:10.1116/5.0098119

Technology roadmap for cold-atoms based quantum inertial sensor in space

Sven Abend, Baptiste Allard, Aidan S. Arnold, Ticijana Ban, Liam Barry, Baptiste Battelier, Ahmad Bawamia, Quentin Beaufils, Simon Bernon, Andrea Bertoldi, Alexis Bonnin, Philippe Bouyer, Alexandre Bresson, Oliver S. Burrow, Benjamin Canuel, Bruno Desruelle, Giannis Drougakis, René Forsberg, Naceur Gaaloul, Alexandre GauguetMatthias Gersemann, Paul F. Griffin, Hendrik Heine, Victoria A. Henderson, Waldemar Herr, Simon Kanthak, Markus Krutzik, Maike D. Lachmann, Roland Lammegger, Werner Magnes, Gaetano Mileti, Morgan W. Mitchell, Sergio Mottini, Dimitris Papazoglou, Franck Pereira dos Santos, Achim Peters, Ernst Rasel, Erling Riis, Christian Schubert, Stephan Tobias Seidel, Guglielmo M. Tino, Mathias Van Den Bossche, Wolf von Klitzing, Andreas Wicht, Marcin Witkowski, Nassim Zahzam, Michał Zawada

Institute of Experimental Physics (5110)

Research output: Contribution to journal › Article › peer-review

Abstract

Recent developments in quantum technology have resulted in a new generation of sensors for measuring inertial quantities, such as acceleration and rotation. These sensors can exhibit unprecedented sensitivity and accuracy when operated in space, where the free-fall interrogation time can be extended at will and where the environment noise is minimal. European laboratories have played a leading role in this
field by developing concepts and tools to operate these quantum sensors in relevant environment, such as parabolic flights, free-fall towers, or sounding rockets. With the recent achievement of Bose–Einstein condensation on the International Space Station, the challenge is now to reach a technology readiness level sufficiently high at both component and system levels to provide “off the shelf” payload for future generations of space missions in geodesy or fundamental physics. In this roadmap, we provide an extensive review on the status of all common parts, needs, and subsystems for the application of atom-based interferometers in space, in order to push for the development of generic technology components.

Original language	English
Article number	019201
Number of pages	31
Journal	AVS Quantum Science
Volume	5
Issue number	1
DOIs	https://doi.org/10.1116/5.0098119
Publication status	Published - 20 Mar 2023

ASJC Scopus subject areas

Electronic, Optical and Magnetic Materials
Condensed Matter Physics
Atomic and Molecular Physics, and Optics
Electrical and Electronic Engineering
Computer Networks and Communications
Physical and Theoretical Chemistry
Computational Theory and Mathematics

Fields of Expertise

Advanced Materials Science

Access to Document

10.1116/5.0098119Licence: CC BY 4.0

Cite this

Abend, S., Allard, B., Arnold, A. S., Ban, T., Barry, L., Battelier, B., Bawamia, A., Beaufils, Q., Bernon, S., Bertoldi, A., Bonnin, A., Bouyer, P., Bresson, A., Burrow, O. S., Canuel, B., Desruelle, B., Drougakis, G., Forsberg, R., Gaaloul, N., ... Zawada, M. (2023). Technology roadmap for cold-atoms based quantum inertial sensor in space. AVS Quantum Science, 5(1), Article 019201. https://doi.org/10.1116/5.0098119

Abend, S, Allard, B, Arnold, AS, Ban, T, Barry, L, Battelier, B, Bawamia, A, Beaufils, Q, Bernon, S, Bertoldi, A, Bonnin, A, Bouyer, P, Bresson, A, Burrow, OS, Canuel, B, Desruelle, B, Drougakis, G, Forsberg, R, Gaaloul, N, Gauguet, A, Gersemann, M, Griffin, PF, Heine, H, Henderson, VA, Herr, W, Kanthak, S, Krutzik, M, Lachmann, MD, Lammegger, R , Magnes, W, Mileti, G, Mitchell, MW, Mottini, S, Papazoglou, D, Pereira dos Santos, F, Peters, A, Rasel, E, Riis, E, Schubert, C, Seidel, ST, Tino, GM, Van Den Bossche, M, von Klitzing, W, Wicht, A, Witkowski, M, Zahzam, N & Zawada, M 2023, 'Technology roadmap for cold-atoms based quantum inertial sensor in space', AVS Quantum Science, vol. 5, no. 1, 019201. https://doi.org/10.1116/5.0098119

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title = "Technology roadmap for cold-atoms based quantum inertial sensor in space",

abstract = "Recent developments in quantum technology have resulted in a new generation of sensors for measuring inertial quantities, such as acceleration and rotation. These sensors can exhibit unprecedented sensitivity and accuracy when operated in space, where the free-fall interrogation time can be extended at will and where the environment noise is minimal. European laboratories have played a leading role in thisfield by developing concepts and tools to operate these quantum sensors in relevant environment, such as parabolic flights, free-fall towers, or sounding rockets. With the recent achievement of Bose–Einstein condensation on the International Space Station, the challenge is now to reach a technology readiness level sufficiently high at both component and system levels to provide “off the shelf” payload for future generations of space missions in geodesy or fundamental physics. In this roadmap, we provide an extensive review on the status of all common parts, needs, and subsystems for the application of atom-based interferometers in space, in order to push for the development of generic technology components.",

author = "Sven Abend and Baptiste Allard and Arnold, {Aidan S.} and Ticijana Ban and Liam Barry and Baptiste Battelier and Ahmad Bawamia and Quentin Beaufils and Simon Bernon and Andrea Bertoldi and Alexis Bonnin and Philippe Bouyer and Alexandre Bresson and Burrow, {Oliver S.} and Benjamin Canuel and Bruno Desruelle and Giannis Drougakis and Ren{\'e} Forsberg and Naceur Gaaloul and Alexandre Gauguet and Matthias Gersemann and Griffin, {Paul F.} and Hendrik Heine and Henderson, {Victoria A.} and Waldemar Herr and Simon Kanthak and Markus Krutzik and Lachmann, {Maike D.} and Roland Lammegger and Werner Magnes and Gaetano Mileti and Mitchell, {Morgan W.} and Sergio Mottini and Dimitris Papazoglou and {Pereira dos Santos}, Franck and Achim Peters and Ernst Rasel and Erling Riis and Christian Schubert and Seidel, {Stephan Tobias} and Tino, {Guglielmo M.} and {Van Den Bossche}, Mathias and {von Klitzing}, Wolf and Andreas Wicht and Marcin Witkowski and Nassim Zahzam and Micha{\l} Zawada",

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AU - Abend, Sven

AU - Allard, Baptiste

AU - Arnold, Aidan S.

AU - Ban, Ticijana

AU - Barry, Liam

AU - Battelier, Baptiste

AU - Bawamia, Ahmad

AU - Beaufils, Quentin

AU - Bernon, Simon

AU - Bertoldi, Andrea

AU - Bonnin, Alexis

AU - Bouyer, Philippe

AU - Bresson, Alexandre

AU - Burrow, Oliver S.

AU - Canuel, Benjamin

AU - Desruelle, Bruno

AU - Drougakis, Giannis

AU - Forsberg, René

AU - Gaaloul, Naceur

AU - Gauguet, Alexandre

AU - Gersemann, Matthias

AU - Griffin, Paul F.

AU - Heine, Hendrik

AU - Henderson, Victoria A.

AU - Herr, Waldemar

AU - Kanthak, Simon

AU - Krutzik, Markus

AU - Lachmann, Maike D.

AU - Lammegger, Roland

AU - Magnes, Werner

AU - Mileti, Gaetano

AU - Mitchell, Morgan W.

AU - Mottini, Sergio

AU - Papazoglou, Dimitris

AU - Pereira dos Santos, Franck

AU - Peters, Achim

AU - Rasel, Ernst

AU - Riis, Erling

AU - Schubert, Christian

AU - Seidel, Stephan Tobias

AU - Tino, Guglielmo M.

AU - Van Den Bossche, Mathias

AU - von Klitzing, Wolf

AU - Wicht, Andreas

AU - Witkowski, Marcin

AU - Zahzam, Nassim

AU - Zawada, Michał

N1 - doi: 10.1116/5.0098119

PY - 2023/3/20

Y1 - 2023/3/20

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AB - Recent developments in quantum technology have resulted in a new generation of sensors for measuring inertial quantities, such as acceleration and rotation. These sensors can exhibit unprecedented sensitivity and accuracy when operated in space, where the free-fall interrogation time can be extended at will and where the environment noise is minimal. European laboratories have played a leading role in thisfield by developing concepts and tools to operate these quantum sensors in relevant environment, such as parabolic flights, free-fall towers, or sounding rockets. With the recent achievement of Bose–Einstein condensation on the International Space Station, the challenge is now to reach a technology readiness level sufficiently high at both component and system levels to provide “off the shelf” payload for future generations of space missions in geodesy or fundamental physics. In this roadmap, we provide an extensive review on the status of all common parts, needs, and subsystems for the application of atom-based interferometers in space, in order to push for the development of generic technology components.

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Technology roadmap for cold-atoms based quantum inertial sensor in space

Abstract

ASJC Scopus subject areas

Fields of Expertise

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MAGSCA - Design, Manufacturing, Validation and Test of the Absolute Scalar Sensor and Associated Electronics for J-MAG / JUICE

Cite this

Technology roadmap for cold-atoms based quantum inertial sensor in space

Abstract

ASJC Scopus subject areas

Fields of Expertise

Access to Document

Other files and links

Fingerprint

Projects

MAGSCA - Design, Manufacturing, Validation and Test of the Absolute Scalar Sensor and Associated Electronics for J-MAG / JUICE

Cite this